Effects of Nanoparticle Geometry and Size Distribution on Diffusion Impedance of Battery Electrodes

Song, Juhyun; Bazant, Martin Z.

doi:10.1149/2.023301jes

Cited by 231 publications

(206 citation statements)

References 43 publications

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“…6,8,20,32,33,40 The low frequency branch (<1 Hz) is associated with the Randles element of ς an , inside TLM an . The values used for L and r are respectively 35 μm and 548 nm, obtained from the FIB/SEM analysis and PSD calculation.…”

Section: Discussionmentioning

confidence: 99%

A Physically-Based Equivalent Circuit Model for the Impedance of a LiFePO₄/Graphite 26650 Cylindrical Cell

Scipioni¹,

Jørgensen²,

Graves³

et al. 2017

J. Electrochem. Soc.

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In this work an Equivalent Circuit Model (ECM) is developed and used to model impedance spectra measured on a commercial 26650 LiFePO 4 /Graphite cylindrical cell. The ECM is based on measurements and modeling of impedance spectra recorded separately on cathode (LiFePO 4 ) and anode (Graphite) samples, harvested from the commercial cell. Modeling of the single-electrode impedance spectra provided information about the electronic and ionic resistance in the porous composite electrodes, as well as the solid state diffusion. Focused Ion Beam (FIB)/Scanning Electron Microscopy (SEM) of anode and cathode samples was used to make 3-D maps of the electrode microstructures and to obtain microstructural data for the ECM. The cylindrical cell continues to be one of the most widely used packaging styles for primary and secondary batteries. The advantages are ease of manufacture and good mechanical stability. The tubular cylinder can withstand high internal pressures without deforming.

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Section: Discussionmentioning

confidence: 99%

A Physically-Based Equivalent Circuit Model for the Impedance of a LiFePO₄/Graphite 26650 Cylindrical Cell

Scipioni¹,

Jørgensen²,

Graves³

et al. 2017

J. Electrochem. Soc.

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“…For intercalation compounds the rate-limiting mechanism is the diffusion of Li + inside the active material. 19 Diffusion of ions gives rise to distinctive impedance patterns characterized by Warburg-like responses as Z ∝ (iω) −1/2 (being ω the angular frequency and i = (−1) 1/2 ). Models based on spatially restricted ion diffusion were proposed to account for intermediate-frequency arcs relaying on a distribution of diffusion lengths 20 or electronic transport limitations.…”

Section: ■ Introductionmentioning

confidence: 99%

Probing Lithiation Kinetics of Carbon-Coated ZnFe₂O₄ Nanoparticle Battery Anodes

et al. 2014

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The investigation of the lithiation−delithiation kinetics of anodes comprising carbon-coated ZnFe 2 O 4 nanoparticles is reported in here. The study confirmed that, as occurring with other conversion electrodes, lithiation of ZnFe 2 O 4 nanoparticles is a multistep process involving the presence of intermediate Li−Zn−Fe−O phases as precursors for the formation of amorphous Li 2 O. A detailed knowledge on the reaction kinetics of the involved electrochemical mechanisms has been achieved by using impedance spectroscopy. It has been observed that lithiation reactions introduce a long delay that limits the electrode charging, not related to diffusion mechanisms. The sloping curve following the conversion plateau of the galvanostatic discharge is connected to a retardation effect in the reaction kinetics. This limitation is seen as an additional resistive process originated by the specific lithiation microscopic features. It is concluded that capacitance spectra allow distinguishing two separate processes: formation of kinetically favored intermediate Li−Zn−Fe−O phases and subsequent reaction to produce highly dispersed LiZn and Fe 0 in an amorphous Li 2 O matrix. A detailed electrical model is provided accounting for the overall electrode lithiation process. ■ INTRODUCTIONLi-ion batteries have become core devices for the consumer electronics industry. Materials for commercial battery electrodes are mostly chosen from a set of intercalation compounds that reversibly accommodate lithium ions in host sites in the lattice without severely distorting the structure. In most transition metal compounds such as LiCoO 2 , LiNi 1−y−z Mn y Co z O 2 , LiFePO 4 , and Li 4 Ti 5 O 12, redox activity is restricted to a few exchanged electrons. Therefore, intercalation materials exhibit intrinsic limitations that make them unviable when high capacity requirements have to be fulfilled as in the case of large scale or automotive applications.1−3 During the past decades a new family of electrode materials operating under the so-called conversion reaction has been intensely studied.4 For these compounds lithiation occurs through the reaction that involves a complete metal reduction as M a X b + (bn)Li ↔ aM + bLi n X, where M = transition metal, X = anion (O, S, N, P, and F), and n = anion formal oxidation state. Conversion reaction is able to accommodate larger amount of Li atoms into the lithium binary compound Li n X, which explains specific capacities exceeding 1000 mAh g −1 as reported for many compounds. Interestingly, conversion materials usually show good reversibility because of the formation of a nanostructured matrix that comprises metallic nanoparticles surrounded by amorphous Li n X phases. Intimate phase contact facilitates reactivity as evidenced by the observation of remaining metallic nanoparticles after extended oxidation/ reduction cycling. 4 Despite their potentialities, conversion compounds present a series of performance limitations that hinders their straightforward application in commercial devices. There...

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“…1(c), has been modeled with a Randles circuit which includes the charge transfer resistance R ct , a constant phase element Q (from which the effective double layer capacitance C dl is calculated according to [19]) and the general finite space Warburg element W GFS [20][21][22], with the impedance: [3] With time constant:…”

Section: Cell Assembly and Testingmentioning

confidence: 99%

Low-Voltage FIB/SEM Tomography for 3D Microstructure Evolution of LiFePO₄/C Electrode

Scipioni¹,

Jørgensen²,

Ngo³

et al. 2015

ECS Trans.

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This work presents an investigation of the degradation mechanisms that occur in LiFePO 4 /C battery electrodes during charge/discharge cycling. Impedance spectra were measured on a fresh electrode and an electrode aged by cycling. The spectra were modeled with an equivalent circuit which indicates that both the ionic and electronic pathways in the electrode were negatively affected by the cycling. Focused Ion Beam/Scanning Electron Microscopy (FIB/SEM) tomography of both electrodes shows that cycling causes agglomerations of Carbon black (CB). In addition to this, Lowvoltage FIB/SEM revealed non-conductive CB in the aged electrode.

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Effects of Nanoparticle Geometry and Size Distribution on Diffusion Impedance of Battery Electrodes

Cited by 231 publications

References 43 publications

A Physically-Based Equivalent Circuit Model for the Impedance of a LiFePO₄/Graphite 26650 Cylindrical Cell

A Physically-Based Equivalent Circuit Model for the Impedance of a LiFePO₄/Graphite 26650 Cylindrical Cell

Probing Lithiation Kinetics of Carbon-Coated ZnFe₂O₄ Nanoparticle Battery Anodes

Low-Voltage FIB/SEM Tomography for 3D Microstructure Evolution of LiFePO₄/C Electrode

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Effects of Nanoparticle Geometry and Size Distribution on Diffusion Impedance of Battery Electrodes

Cited by 231 publications

References 43 publications

A Physically-Based Equivalent Circuit Model for the Impedance of a LiFePO4/Graphite 26650 Cylindrical Cell

A Physically-Based Equivalent Circuit Model for the Impedance of a LiFePO4/Graphite 26650 Cylindrical Cell

Probing Lithiation Kinetics of Carbon-Coated ZnFe2O4 Nanoparticle Battery Anodes

Low-Voltage FIB/SEM Tomography for 3D Microstructure Evolution of LiFePO4/C Electrode

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Resources

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A Physically-Based Equivalent Circuit Model for the Impedance of a LiFePO₄/Graphite 26650 Cylindrical Cell

A Physically-Based Equivalent Circuit Model for the Impedance of a LiFePO₄/Graphite 26650 Cylindrical Cell

Probing Lithiation Kinetics of Carbon-Coated ZnFe₂O₄ Nanoparticle Battery Anodes

Low-Voltage FIB/SEM Tomography for 3D Microstructure Evolution of LiFePO₄/C Electrode